DE804692C - Combined radio transmitting and receiving device - Google Patents

Description

In the known combined radio transmitting and receiving devices, which as a result of received Characters automatically send reply characters, the field strength of the reply character is independent of the field strength of the received character. This has disadvantageous interference effects as a result, and especially if there is a larger one within a given geographic area Number with ultra-high frequency vibrations

ίο working transmitting and receiving devices available is.

According to the invention, this interference can be considerably reduced and made available The standing frequency band can be used much better that the field strength of the reply characters sent is made dependent on the field strength of the received characters, in particular in such a way that they are in inverse proportion to the field strength of the received character stands.

Such a dependence of the field strength of the response character on the field strength of the received Character is particularly advantageous when at least one of the communicates with one another standing combined transmitting and receiving devices is movable, since then the Output power of one device according to the changing mutual distance between the two Facilities and / or the changing other transfer conditions. The thereby Conditional, often considerable, reduction in output power also increases the service life of the device.

In connection with the control of the strength of the response character, which is dependent on the reception field strength sensitivity can also be beneficial

of the receiving part of the device can be regulated in the same way in order in this way to the im Receiver generated background noise to reduce, which is especially true when working in the ultra-high frequency range is of great importance above 100 MHz.

The invention is explained in more detail with reference to the drawing, in which FIGS. 1 and 2 are a partially schematic representation of an embodiment of a combined transmitting and receiving device according to the invention, while FIG. 3 shows another embodiment of a transmitting and receiving device according to the invention.
The combined transmitting and receiving device according to FIGS. 1 and 2 comprises an oscillating circuit 10 which is connected to a tube 11 which forms part of a pendulum frequency receiver and transmitter. An antenna 22 grounded via an adjustable capacitor 23 is inductively coupled to the coil 12 belonging to the circuit 10. A parallel resonance circuit consisting of the coil 12 and a variable capacitor 13 is connected to the anode of the tube 11. A grid discharge resistor 14 connected in parallel to a capacitor 15 is connected between the control grid of the tube and one end of the coil 12, while the cathode of the tube is grounded. The center of the coil 12 is grounded via a high-frequency choke coil 16 and the secondary winding of a transformer 17. The anode of a rectifier diode, the cathode of which is grounded, is also connected to the anode of the tube 11 via a coupling capacitor 18. A load resistor 20 is connected to this diode 19 via a choke coil 21.

The device also contains means that are sensitive to the received field strength. These include a control device 60 to be described in more detail below, the input circuit of which is connected to the load resistor 20. The unit 60 acts on organs which regulate the strength of the characters transmitted by the device in inverse proportion to the strength of the characters received. These organs consist of the extinguishing voltage amplifier tube 41, the rectifier diode 50 and an amplifier 54. The input circuit of the tube 41 is connected on the one hand to the output circuit of a conventional extinguishing voltage generator 40 via a coupling capacitor 42 and on the other hand via a resistor 43 to the output circuit of the unit 60. The erase voltage amplifier circuit comprises a balanced anode circuit consisting of a coil 44 and a capacitor 45 which is connected between the anode of the tube 41 and an anode voltage source + B. The screen grid of the tube 41 receives its voltage from the voltage source + Sc, while the cathode of this tube is grounded via a resistor 46 bridged by the capacitor 47. The anode of the tube 41 is inductively coupled to the anode of the rectifier diode 50 by means of a coil 48 which can be tuned by the capacitor 49. The cathode of the rectifier 50 is connected via [a of the shunt capacitors 51, 52 and the choke coil 53 composed Siebnetzwerk and via the line 82 to the connected to the anode of the amplifier 54 the primary winding of the transformer 17th The cathode of amplifier 54 is grounded, while its screen grid is connected to voltage source + B and its control grid is connected to voltage source - C via a resistor 55. A block capacitor 56 is connected by means of the line 81 between a point of the coil 44 and the connection point of the choke coil 16 with the secondary coil of the transformer 17.

Furthermore, the device contains means for generating the characters for the received characters giving answer mark. These means comprise an amplifier 57, which by means of the line 80 is connected between the output circuit of the control unit 60 and a transmission character generator 58. This send character generator consists of means known per se for generating one answer character each for each input character of a predetermined type, for example from a multivibrator. It is connected to the input circuit of the amplifier 58 via a coupling capacitor 59.

If one disregards the effect of the control unit 60, this is the mode of operation of the device as follows:

An alternating voltage is fed to the resonance circuit 12, 13 of the pendulum feedback circuit containing the tube 11 from the quenching voltage generator 40 via the quenching voltage amplifier 41, which alternately makes the pendulum feedback circuit oscillatable and non-oscillatory, the frequency of this oscillation being equal to the frequency of the quenching voltage. Each symbol received by the antenna 22 and fed to the resonance circuit 12, 13 has the effect that the oscillations in this circle begin earlier and reach a higher amplitude than when no symbol is received. These oscillations of increased amplitude are fed to the rectifier 19, and the resulting modulation components of the received character cause a pulsating DC voltage at the resistor 20, which, for example, in the case of receiving pulse-shaped characters with a steep front edge, can have the form of the character R. This mode of operation of the device is that of a conventional pendulum feedback receiver and therefore does not require any further explanation.

The mode of operation of the transmitting part of the device is to be described on the assumption that the received character consists of an R pulse. This pulse is fed to the input circuit of the control unit 60, and the character resulting there in the manner to be described below passes via the amplifier 57 to the transmission character generator 58, which generates an auxiliary character containing an output character T of predetermined form and feeds it to the amplifier 54. Units 57 and 58 are designed to respond to input characters with a

address a wide amplitude range. The rectifier supplies the anode voltage for the amplifier 54 50 by rectifying its matched anode-cathode circuit from the matched Anode circuit 44, 45 of the extinguishing voltage amplifier 41 supplied vibrations.

The pulse fed from unit 58 to amplifier 54 is amplified and its amplitude is further enlarged by the transformer 17.

The pulse then passes through the high-frequency choke coil 16 to the resonance circuit 12, 13 and increases the anode potential of the tube 11 so that the circuit 10 can operate as a transmitter circuit. In addition, the pulse modulates the high-frequency symbol generated in the circle 10, so that the antenna 22 emits a pulse-modulated carrier symbol of the waveform T as a result of the reception of a pulse R.

The device described above is therefore

Such a combined pendulum feedback receiver and transmitter provided with a common receiving and transmitting tube for transmitting response characters to received excitation characters , a trimmer 69, an amplifier 63 and a blocking capacitor 65 are connected to a rectifier diode 64. The anode of the rectifier 64 is grounded via a resistor 66 bridged by a capacitor 68, while its cathode is grounded via a resistor OS. The extinction voltage amplifier 41 is connected to the anode of the rectifier 64, while its cathode is connected to the input circuit of the amplifier 57. The operation of the entire device, including that of the control unit 60, will now be considered. The received pulse 7? is fed to the input circuit of the control unit 60, and a certain time after the reception of this pulse, the transmitting part of the device is caused by the voltage generated in the rectifier 64 to transmit a response character with a relatively long duration. This character is also received by the receiver and rectified in order to then be fed to the control unit 60 in the form of a pulse RT together with the next pulse R. In the limiter 61 a pair of time-separated symbol pulses of the waveform R and RT are obtained, which are fed to the differentiating circuit 62. The limiter 61 is designed so that it cuts off the tip of the extremely strong pulse RT , but allows the relatively weak pulse R to pass without changing its waveform, even if the strength of this pulse changes within wider limits. The parameters of the differentiating circle 62 are chosen so that this circle only lets through characters with a steep end flank, the output character shown in the drawing above this circle being obtained. This is fed to the trimmer 69, which is only sensitive to characters of a certain polarity and therefore forwards a character of the shape shown in the drawing above the trimmer 69 to the amplifier 63. After the amplification which takes place here, during which all remaining traces of the emitted pulse are eliminated at the same time, the character is fed partly to the amplifier 57 and partly to the rectifier 64. A negative DC voltage then arises in the rectifier and reaches the control electrode of the extinction voltage amplifier 41 via the resistor 43.

In the output circuit of the control unit 60 there is thus one of the strength of the received character inversely proportional DC control voltage, which appears as a variable negative bias the control grid of the extinction voltage amplifier 41 operating as a ^ 4 amplifier acts. At the reception a strong sign therefore results in a strong negative bias, which increases the degree of amplification of the tube 41 is reduced considerably. This will increase the size of the output circle AC voltage generated in this tube and consequently also the size of the voltage across the capacitor 56 the circuit 10 of the receiver supplied alternating voltage, so that the sensitivity of the recipient changes in inverse proportion to the strength of the characters received.

By reducing the gain of the erase voltage amplifier 41, the The magnitude of the AC voltage supplied to the rectifier 50 decreases, which is a decrease the DC voltage supplied to the anode of the amplifier 54, so that this Repeater the response character triggered by the received character of the unit 58 with reduced Amplitude transferred to the transformer 17 and the high frequency circuit 10, its Vibrations can be controlled by this sign of reduced amplitude. As a result, changes the strength of the reply character sent is inversely proportional to the strength of the received character. On the other hand, when a weak character is received, the unit 60 increases by increasing the gain of the extinction voltage amplifier 41, both the sensitivity no possibility of the receiving part of the device as well as the strength of the reply character sent.

From FIGS. 1 and 2 it is evident that the amplifier 54 only uses its anode voltage from the organs 40 and 41 supplying the extinction voltage via the rectifier 50. These Organs are suitable for supplying the named amplifier with the high anode voltage which he needs to send out a strong response character when receiving weak characters.

Of course, instead of the common receiving and transmitting tube 11, separate, with Tubes operating at the same or different frequencies and separate antennas for reception and intended for the broadcast.

The device according to FIG. 3 contains an over-

Positioning receiver 70 and a transmitter 72 which is separate from this and which is connected to the receiver via a control unit 73, which can be the same as the control unit 60 of the device according to FIGS. 1 and 2. The transmitter 72 is connected partly to an antenna 78 and partly to the output circuit of a demodulator JJ of the receiver 70. The heterodyne receiver consists of an antenna 71, a high frequency amplifier 74, a frequency converter 75, an intermediate frequency amplifier 76 and the demodulator Jj. The control unit 73 is connected to the demodulator 77 and to one or more stages of the units 74, 75 and 76.

The characters received by the antenna 71 are amplified in the amplifier 74 and converted in the frequency converter 75 into intermediate-frequency characters which, after being amplified in the amplifier 76, reach the demodulator Jj . The resulting modulation components of the characters are fed to the control unit 73, in which a control voltage proportional to the strength of the received characters is generated, which on the one hand controls the sensitivity of the receiver and on the other hand the strength of the response characters sent in inverse proportion to the strength of the received characters. For the latter purpose, the S expensive voltage can, for example, be fed to a control element in the modulator circuit of the transmitter. The modulation components resulting in the demodulator Jj are also fed to the transmitter 72 in order to trigger the transmission of the response characters in this.
Although the invention has been described in connection with amplitude-modulated pulse symbols, it is evident that it is also applicable to devices for receiving and transmitting frequency- or phase-modulated symbols or unmodulated, interrupted carrier symbols. In certain cases, e.g. B. in equipment for the transmission of messages between a fixed station and a vehicle, it may be desirable to regulate the strength of the response characters sent depending on the strength of the received unmodulated carrier wave. In such cases, a suitable control voltage can be obtained from the rectified carrier wave by means of a rectifier.

In this context, the answer sign is to be understood as any type of sign which a transmitting station receives in the pursuit of a character sent by it. This Answer characters can be amplitude-, phase- or frequency-modulated or a unmodulated carrier characters as well as a reflected or an ultrasonic character.

Claims (1)

Patent claims: 1. Combined radio transmitting and receiving device for receiving from a character source sent characters and for the automatic return of reply characters by means for regulating the strength of the response characters as a function of the strength of the characters received. 2. Device according to claim 1, characterized in that that the strength of the response characters changes in inverse proportion to the strength of the received characters. 3. Device according to claim 1 or 2, characterized by means of similar regulation of the sensitivity of their receiving part. 4. Device according to one or more of the preceding claims, characterized by an amplifier for amplifying the transmitted response characters and means for regulating this amplifier depending on the strength of the received characters. 5; Device according to Claim 4, characterized by a pendulum frequency receiver and - Transmitter with a common erasure voltage source, an amplifier for amplifying this Erase voltage and means for regulating this amplifier as a function of the strength of the received characters. 6. Device according to claim 5, characterized in that the extinction voltage amplifier supplies the anode voltage for the transmitter amplifier. 1 sheet of drawings 422 4.51